JP2011205776A - Electronic device, electronic device system, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electronic device, an electronic device system, and a program which can detect failure certainly and easily even when failure due to high temperature occurs in the power system of an electronic device.SOLUTION: When a sign of failure due to high temperature is detected in the power systems (110, 111, and 112) of a first MFP(100) by a sign detector (107), a second MFP(200) communicates with the first MFP(100) in a predetermined frequency, and receives ON/OFF information, sign occurrence information, and temperature information detected by the controller (101) of the first MFP(100), and in case that the temperature information can not be obtained, it determines that the failure due to high temperature has occurred in the first MFP, and transmits failure occurrence information to a management center (401) via a network (400).

Description

  The present invention relates to an electronic device, an electronic device system, and a program capable of detecting an abnormality due to high temperature.

  Conventionally, as an electronic device, for example, there is a technique that can be applied to an accident analysis of occurrence of abnormality due to high temperature disclosed in Patent Document 1. According to this electronic device, a plurality of thermistors are provided to detect the temperature of the fixing device, the temperature inside the device, the temperature outside the device, the input voltage of the AC input power supply, the detection of the DC voltage inside the device, etc. Thus, information necessary for accident analysis is detected, and this information is stored in a storage device.

  In addition, a communication unit, power management unit, thermal sensor, and smoke detection sensor are provided in the printing device independently of the main body, and when the temperature exceeds the specified temperature for a certain period of time or smoke is detected, the printing device's A technique has been proposed in which the main power is turned off to notify the administrator (see, for example, Patent Document 2).

JP-A-10-254309 JP 2003-154739 A

  An object of the present invention is to provide an electronic device, an electronic device system, and a program capable of reliably and easily detecting an abnormality even when an abnormality due to high temperature occurs in a power supply system unit of the electronic device.

  The electronic device according to claim 1 is a case where an abnormality detection means for detecting an abnormality due to a high temperature, a sign detection means for detecting a sign of an abnormality due to a high temperature, and a sign of an abnormality due to a high temperature detected by the sign detection means Output means for outputting power-on information, sign occurrence information, and a detection result by the abnormality detection means.

  According to a second aspect of the present invention, in the electronic device according to the first aspect of the present invention, a plurality of the abnormality detecting means are provided for a plurality of target portions.

  According to a third aspect of the present invention, in the electronic device according to the first or second aspect, the sign detection unit detects an abnormality in voltage or current in the power supply circuit.

  Furthermore, an electronic device system according to a fourth aspect of the present invention provides an abnormality detection means for detecting an abnormality due to high temperature, a sign detection means for detecting a sign of abnormality due to high temperature, and a sign of abnormality due to high temperature by the sign detection means. When detected, based on the output result of the first electronic device having the power-on information, the sign occurrence information and the output means for outputting the detection result by the abnormality detecting means, and the output result of the output means of the first electronic device And a second electronic device having a determining means for determining whether or not an abnormality due to a high temperature has occurred in the first electronic device.

  According to a fifth aspect of the present invention, in the electronic device according to the fourth aspect of the present invention, the determination means is configured such that the first electronic device is independent of whether the power is turned on according to the power-on information. When the detection result by the abnormality detection means is not obtained, it is determined that an abnormality due to high temperature has occurred in the first electronic device.

  According to a sixth aspect of the present invention, in the electronic device system according to the fourth or fifth aspect of the present invention, the second electronic device starts detection of a sign by the sign detection means of the first electronic device. In this case, it further has communication control means for starting communication with the first electronic device.

  According to a seventh aspect of the present invention, in the electronic device system according to the fourth or fifth aspect of the present invention, the detection of the sign by the sign detection means of the first electronic device is completed in the second electronic device. In this case, the apparatus further includes communication control means for ending communication with the first electronic device.

  An electronic device system according to an eighth aspect of the present invention is the electronic device system according to any of the fourth to seventh aspects, wherein the second electronic device is detected by a sign detection means of the first electronic device. If so, the electronic device further includes prohibiting means for controlling the power supply of the second electronic device to be prohibited.

  An electronic device system according to a ninth aspect of the present invention is the electronic device system according to any of the fourth to eighth aspects, wherein the first electronic device is based on an output result of the output means of the first electronic device. The electronic device further includes a third electronic device further comprising determination means for determining whether or not an abnormality due to high temperature has occurred.

An electronic device system according to a tenth aspect is the invention according to the first or second aspect,
According to a third aspect of the present invention, there is provided the electronic device according to the ninth aspect, wherein the third electronic device is configured such that when the second electronic device is powered off, It is determined whether an abnormality due to a high temperature has occurred in the first electronic device on behalf of the electronic device.

  Furthermore, the program of the invention described in claim 11 is provided with an abnormality detection step for detecting an abnormality due to a high temperature, a sign detection step for detecting a sign of an abnormality due to a high temperature, and a power-on information when a sign of an abnormality due to a high temperature is detected. And an output step of outputting the sign occurrence information and the detection result by the abnormality detecting means.

  According to the first and eleventh aspects of the present invention, when an abnormality due to high temperature occurs in the power supply system section of the electronic device, even if the electronic device cannot detect the abnormality, the management center that manages the abnormality can be used. The apparatus can reliably and easily detect an abnormality.

  According to the invention described in claim 2, it is possible to grasp the site where the abnormality has occurred.

  According to the third aspect of the present invention, even when an abnormality due to high temperature occurs in the power supply system of the electronic device, a sign of abnormality can be reliably and easily detected.

  Further, according to the invention described in claim 4, when an abnormality due to high temperature occurs in the first electronic device, the second electronic device as another device can reliably and easily detect the abnormality. .

  According to the fifth aspect of the present invention, when an abnormality due to high temperature occurs in the power supply system section of the first electronic device, even if the first electronic device cannot detect the abnormality, the first electronic device The apparatus can reliably and easily detect an abnormality.

  In addition, according to the invention described in claim 6, it is possible to suppress the processing load of the entire electronic device system as compared with a configuration not having this configuration.

  Further, according to the invention described in claim 7, when there is no sign of an abnormality caused by a surge such as lightning, the processing load on the entire electronic device system can be suppressed as compared with the case without this configuration. it can. In addition, when the first electronic device is normally turned off, it can be prevented from erroneously determining that an abnormality has occurred, and the processing load on the entire electronic device system can be suppressed.

  According to the eighth aspect of the present invention, in the period when the abnormality of the first electronic device has occurred, the abnormality detection by the second electronic device can be reliably performed as compared with the case without the present configuration. Can be maintained.

  According to the ninth aspect of the present invention, when an abnormality due to high temperature occurs in the first electronic device, the degree of freedom in selecting an abnormality detection device increases.

  According to the invention described in claim 10, when the abnormality detection function of the second electronic device stops normally, when the abnormality due to high temperature occurs in the first electronic device, this configuration is not provided. In comparison, abnormality detection in the electronic device system can be maintained quickly and flexibly.

It is a block diagram which shows schematic structure of the electronic device system which concerns on embodiment of this invention. It is a wave form diagram which shows an example of the voltage waveform which concerns on embodiment of this invention. It is a timing chart explaining the operation | movement and state of an electronic device system after the abnormality sign is detected other than the power supply system part which concerns on embodiment of this invention. It is a timing chart explaining operation | movement and a state of an electronic device system after the abnormality sign is detected in the power supply system | strain part which concerns on embodiment of this invention. It is a timing chart explaining operation | movement and a state of an electronic device system, after the abnormal sign by the lightning which concerns on embodiment of this invention is detected. 6 is a timing chart for explaining the operation and state of the electronic device system including ON / OFF information of the first MFP and permission to stop power supply of the second MFP after a sign of abnormality according to the embodiment of the present invention is detected. . Operation and state of electronic device system when third MFP detects occurrence of abnormality in first MFP on behalf of second MFP after detection of abnormality sign according to an embodiment of the present invention is described. It is a timing chart to do.

  Embodiments of the present invention will be described below with reference to the drawings.

  First, the configuration of an electronic device system 10 according to an embodiment of the present invention will be described with reference to FIG. FIG. 1 is a block diagram showing a schematic configuration of the electronic device system 10 according to the embodiment of the present invention.

  In FIG. 1, an electronic device system 10 includes, for example, a first MFP (Multi-Function Peripheral) 100, a second MFP 200, a third MFP 300, which are arranged in an office that is an isolated space. A network 400, a management center 401, PCs 402 and 403 as terminals, and a commercial power source 500 are provided.

  The first MFP 100, the second MFP 200, and the third MFP 300 are examples of the “electronic device” according to the present invention. For example, a multifunction device having functions of each OA device such as a printer, a facsimile (FAX), and a copying machine. In addition to printing an image on a recording medium such as paper in response to a print instruction from the PC 402, 403, etc., for example, the image data and the transmission source number notification signal input from the PC 402, 403, etc. are transmitted through the network 400 by the FAX function. To the outside of the electronic device system 10. The PCs 402 and 403 may be terminals other than the PC, and the network 400 may be wired or wireless.

  As shown in FIG. 1, each of the first MFP 100, the second MFP 200, and the third MFP 300 is connected to a commercial power source 500 (for example, AC 100V).

  The first MFP 100 is connected to the power switch 110 that switches the power supplied from the commercial power source 500 to an energized state or a non-energized state by being switched on or off, and the power switch 110 and power wiring The power supply 110 is connected to the first low-voltage power supply 111 that converts power supplied from the commercial power supply 500 to the direct current power of the first voltage level (for example, 5V), and the power switch 110, and the power switch 110 and the power supply wiring 115. And a second low-voltage power source 112 that converts electric power supplied from the commercial power source 500 into DC power at a second voltage level (for example, 24 V). The power switch 110, the first low-voltage power supply 111, the second low-voltage power supply 112, and the power supply wiring 115 constitute a power supply system section of the first MFP 100, and the power supply wiring 115 constitutes a “power supply circuit” in the present invention. .

  The first MFP 100 also includes a UI (User Interface) unit 105 provided with a display unit for displaying operation buttons for inputting various operation instructions such as a copy operation and various messages, and the like. A controller 101 for controlling the operation of the entire apparatus, and a latent image is formed on the photosensitive drum by electrophotography based on the image data, and a toner image developed by attaching toner to the formed latent image is recorded on a recording sheet. An image forming unit 106 for transferring the toner image, a fixing unit 108 for fixing the toner image transferred to the recording sheet by heating and pressurizing the recording sheet, and an optional device 109 that can be selected.

  Supplementally, the option device 109 is connected to expand or add the function of the first MFP 100, for example, a paper feeder (Paper Feeder) for increasing the size of paper that can accommodate and use a large amount of paper. And various optional devices such as a double-sided printing unit for adding a double-sided printing function and a post-processing device (finisher) for performing processing on electronic paper.

  As shown by a solid line in FIG. 1, a sign detection unit 107, a fixing unit 108, and an optional device 109, which will be described later, are connected to a power switch 110 and are connected to a commercial power source 500 via the power switch 110 and the power wiring 115. Power is being supplied. The controller 101 is connected to the first low-voltage power supply 111 and is supplied with power from the first low-voltage power supply 111. The UI unit 104 and the image forming unit 106 are connected to the second low-voltage power source 112, and power is supplied from the second low-voltage power source 112.

  The controller 101 includes a CPU (central processing unit) 102 that controls the operation of the entire apparatus, a ROM (not shown) in which various programs including a control program are stored in advance, and a RAM (not shown) in which various data are temporarily stored. 1), an HDD (hard disk drive) 103 that stores and holds various data, and an interface (I / F) that is connected to the network 400 and transmits / receives communication data to / from external devices via the network 400 Part 104 is provided.

  The controller 101, the UI unit 105, the image forming unit 106, and the sign detection unit 107 are connected to each other via a bus BUS (not shown). Therefore, the controller 101 can grasp the operation state of the user with respect to the operation buttons provided in the UI unit, and can control the operations of the image forming unit 106 and the sign detection unit 107, respectively. Further, the controller 101 can control the display of a message on a display unit provided in the UI unit 105.

  The first MFP 100 is provided with a temperature sensor 113 in each target part other than the power supply system part that is a target for detecting an abnormality due to high temperature in addition to the power supply system part. More specifically, as shown in FIG. 1, the temperature of each of the UI unit 105, the image forming unit 106, the fixing unit 108, the optional device 109, and the wiring unit (not shown) is set as a target portion other than the power supply system unit. Sensors 113a to 113e are provided.

  Further, in the first MFP 100, a temperature sensor 114 is provided in each target part of the power supply system unit that is a detection target of abnormality due to high temperature in the power supply system unit. More specifically, as shown in FIG. 1, temperature sensors 114a to 114d are provided in the first low-voltage power supply 111, the second low-voltage power supply 112, the power switch 110, and the power supply wiring 115 as target portions of the power supply system section. Yes.

  In the embodiment of the present invention, the installation location of the temperature sensor 113 and the temperature sensor 114 may have various aspects as long as it can detect an abnormality due to high temperature in the power supply system unit other than the power supply system unit. . For example, temperature sensors may be provided at the arrangement positions of the various devices in the first MFP 100, the upper part of the apparatus, or the lower part of the apparatus.

  As shown by the dotted lines in FIG. 1, each of the temperature sensor 113 and the temperature sensor 114 is connected to the controller 101, and detects the temperature of the target portion where the temperature sensor 113 and the temperature sensor 114 are provided under the control of the controller 101. . Based on the temperature detected by the temperature sensor 113 and the temperature sensor 114, the controller 101 determines whether an abnormality due to high temperature has occurred in each device or each target part.

  The first MFP 100 is provided with a sign detection unit 107 that detects a sign of abnormality due to high temperature. As described above, since the sign detection unit 107 is supplied with power from the commercial power supply 500 via the power switch 110 and the power supply wiring 115, when an abnormality due to high temperature occurs, Waveform abnormalities such as spike voltage, voltage drop, and current drop occur in the voltage waveform and current waveform as precursors. In addition, the waveform abnormality of the voltage waveform of the electric power supplied via wiring and a current waveform generate | occur | produces by surges, such as a lightning besides the sign of abnormality by high temperature, and the frequency is the same.

  An example of the voltage waveform detected by the sign detection unit 107 will be described with reference to FIG. FIG. 1 is a waveform diagram showing an example of a voltage waveform according to the embodiment of the present invention.

  2A shows a voltage waveform of power supplied through the power supply wiring 115, and FIG. 2B shows a voltage waveform obtained by full-wave rectifying the voltage waveform of FIG. 2A. It is shown. 2C shows a voltage waveform in which a voltage drop has occurred, and FIG. 2D shows a voltage waveform obtained by full-wave rectification of the voltage waveform in FIG. 2C.

  The sign detection unit 107 detects a zero cross point (a point where the voltage becomes 0 V) of the supplied AC power and obtains the period T, and, for example, full-wave rectifies the supplied AC power using a diode bridge or the like. The abnormality of the voltage waveform is detected by obtaining the voltage value at the timing of the cycle T / 2 from the zero cross point of the full-wave voltage waveform. The sign detection unit 107 is connected to the controller 101 as shown by the dotted line in FIG. 1, and notifies that a waveform abnormality has occurred when a voltage waveform abnormality is detected as a sign. Based on the notification from the sign detection unit 107, the controller 101 detects whether an abnormality in the voltage waveform of the supplied power has occurred.

  In addition, although the sign detection unit 107 according to the embodiment of the present invention has been described with respect to detecting a sign of abnormality due to high temperature from the abnormality of the voltage waveform and the abnormality of the current waveform, the present invention is not limited to this. For example, a sign of abnormality due to high temperature may be detected by detecting smoke generated at a high temperature with a smoke detection sensor. Moreover, it is good also as what detects the deformation | transformation etc. of a board | substrate by high temperature.

  Similarly to the first MFP 100, each of the second MFP 200 and the third MFP 300 includes controllers 201 and 301 that control the operation of the entire apparatus, and each of the controllers 201 and 203 controls the operation of the entire apparatus. CPUs 202 and 302, HDDs 203 and 303 that store and store various data, and I / F units 204 and 304 that are connected to the network 400 and transmit / receive communication data to / from external devices via the network 400. Yes.

  Next, with reference to FIG. 3 to FIG. 7, an operation for detecting the occurrence of abnormality by the electronic device system 10 will be described.

  With reference to FIG. 3, an operation for detecting an abnormality when an abnormality occurs in a part other than the power supply system unit of the first MFP 100 will be described. FIG. 3 is a timing chart for explaining the operation and state of the electronic device system after a sign of abnormality is detected in addition to the power supply system unit according to the embodiment of the present invention. In FIG. 3, in the vertical direction, in order from the top, the sign detection count Nf of the first MFP 100, the detected temperature TPdt of the first MFP 100, the operating state of the temperature abnormality information notification of the first MFP 100, and the second MFP 200 The operation state of temperature information acquisition, the result of abnormality determination of the second MFP 200, the operation state of temperature abnormality information notification of the second MFP 200, and the operation state of temperature information transmission of the second MFP 200 are shown. A common time is represented on the axis.

  As shown in FIG. 3, when the sign detection number Nf of the first MFP 100 detected by the sign detection unit 107 exceeds the reference number Nf0 at time T0, a waveform abnormality is detected as a sign that an abnormality due to high temperature occurs. The controller 101 is notified of the occurrence. The controller 101 detects the temperature by the temperature sensors 113 and 114 at a preset frequency, and whether or not an abnormality due to high temperature has occurred in each target part based on the temperature detected by the temperature sensors 113 and 114. And the detected temperature information is stored in the HDD 103. As described above, by storing the temperature information detected by each temperature sensor 113 in the HDD 103, when an abnormality due to a high temperature occurs, analysis of the abnormal part becomes easy. The temperature information stored in the HDD 103 is preferably periodically deleted that is older than a certain period.

  Also, at this time T0, that is, when the sign detection number Nf of the first MFP 100 detected by the sign detection unit 107 exceeds the reference number Nf0, the I / F unit 104 of the first MFP 100 The ON / OFF information indicating that the power supply of the MFP is ON or OFF, the occurrence of a sign of abnormality (hereinafter abbreviated as “signature occurrence information”), and the temperature information stored in the HDD 103 are stored in the second MFP 200. Transmit to the I / F unit 204. When the start information of the sign occurrence information transmitted from the I / F unit 104 side is received, the I / F unit 204 of the second MFP 200 passes the network 400 to the I / F unit 104 of the first MFP 100. The communication is performed periodically, and the ON / OFF information, the sign occurrence information, and the temperature information of the first MFP 100 are received, that is, the operation state of the second MFP 200 for acquiring the temperature information is YES. At this time T0, the initial value of the result of the abnormality determination of the second MFP 200 is set to normal (OK state in the figure).

  Here, the reference number Nf0 is a value serving as a reference for determining whether or not to determine whether an abnormality has occurred based on the detected temperature, and is stored in the HDD 103 in advance. The reference number Nf0 may be determined in advance by an experiment using an actual machine, a computer simulation based on a design specification of the electronic device system 10 or the first MFP 100, or the like. For example, it may be set in advance as a fixed value such as 10 times within 3 minutes, or may be a function value that is variable in accordance with the value of some parameter in real time. Similarly, the communication frequency from the second MFP 200 to the first MFP 100 is a value stored in the HDD 103, and may be set as a fixed value in advance, for example, once every 30 seconds, or the number of indication detections, for example The function value may be variable in real time according to the parameter value.

  In the electronic apparatus system 10 according to the embodiment of the present invention, the I / F unit 204 of the second MFP 200 is configured to periodically communicate with the first MFP 100 via the network 400. As long as the second MFP 200 can detect an abnormality due to high temperature in the first MFP, various modes may be provided. For example, the I / F unit 104 of the first MFP 100 may be configured to periodically communicate with the I / F unit 204 of the second MFP 200 via the network 400, or may be configured to communicate with the first MFP 100 and the first MFP 100. The two MFPs 200 may be configured to communicate with each other.

  Thereafter, when the temperature of the target portion other than the power supply system unit detected by the temperature sensor 113 exceeds the reference temperature TP0 at time T1, and the controller 101 determines that an abnormality due to high temperature has occurred in other than the power supply system unit. Then, a message indicating that an abnormality due to high temperature has occurred is displayed on the display unit of the UI unit 105. Further, at this time T1, since the first MFP 100 can issue an abnormality notification, an abnormality due to high temperature has occurred in the I / F unit 104 of the first MFP 100 other than the power supply system unit of the first MFP 100. (Hereinafter abbreviated as “temperature abnormality information”) is notified to an external device such as the management center 401 that manages the abnormality. Here, the reference temperature TP0 is a value serving as a reference when determining whether or not an abnormality due to high temperature has occurred, and is stored in the HDD 103 in advance. The reference temperature TP0 may be set in advance as a fixed value such as 70 ° C., or may be a function value that is variable in real time according to a value of some parameter.

  In the embodiment of the present invention, when an abnormality due to high temperature occurs, a message indicating that an abnormality due to high temperature has occurred is displayed on the display unit or the like of the UI unit 105 to notify the user. The invention is not limited to this. For example, the UI unit 105 or the like may be notified to the user using voice.

  When temperature abnormality information is transmitted to the management center 401 by the first MFP 100, the I / F unit 204 of the second MFP 200 performs regular communication to the I / F unit 104 of the first MFP 100, and ON. / OFF information, sign generation information, and temperature information of the first MFP 100 are stopped, that is, the operation state of the second MFP 200 for acquiring temperature information is NO. Further, as shown in FIG. 3, since the temperature abnormality information notification is performed by the first MFP 100, the operation state of the temperature abnormality information notification and the operation state of the temperature information transmission to the management center 401 by the second MFP 100 is NO. It is maintained.

  As described above, when an abnormality due to high temperature occurs in a part other than the power supply system of the first MFP 100, the first MFP 100 itself notifies the management center 401 of temperature abnormality information, thereby reliably and easily detecting the abnormality. Can be done.

  With reference to FIG. 4, an operation of detecting an abnormality when an abnormality occurs in the power supply system unit of the first MFP 100 will be described. FIG. 4 is a timing chart for explaining the operation and state of the electronic device system 10 after a sign of abnormality is detected in the power supply system unit according to the embodiment of the present invention. In FIG. 4, parts that are the same as those in FIG.

  As shown in FIG. 4, when the sign detection number Nf of the first MFP 100 detected by the sign detection unit 107 exceeds the reference number Nf0 at time T0, the sign transmitted from the I / F unit 104 side. When the start information of the generated information is received, the I / F unit 204 of the second MFP 200 periodically communicates with the I / F unit 104 of the first MFP 100 via the network 400, and the ON / OFF information, The predictive occurrence information and the temperature information of the first MFP 100 are received, that is, the operation state of the temperature information acquisition of the second MFP 200 is YES. The initial value of the result of the abnormality determination of the second MFP 200 is set to normal (OK state shown). Further, the temperature information may be communicated limited to data of the temperature sensor 114 that detects the power supply system unit.

  Thereafter, at time T2, an abnormality has occurred in the power supply system unit of the first MFP 100, so the temperature of the temperature sensor 114 in the power supply system unit rises. However, before the reference temperature TP0 is reached, the power supply of the first MFP 100 has failed. When turned off, periodic communication from the I / F unit 204 of the second MFP 200 to the I / F unit 104 of the first MFP 100 is also disabled, and the ON / OFF information, the sign occurrence information, and the first MFP 100 The temperature information can no longer be received. At this time, since the temperature information of the first MFP 100 is not obtained, the second MFP 200 sets the abnormality determination result to be abnormal (NG state in the figure).

  Then, as shown in FIG. 4, a postponement period (that is, a time difference between the time T2 and the time T3) is set in advance in order to ensure the result of abnormality determination, and until this postponement period elapses, Periodic communication continues from the I / F unit 204 of the second MFP 200 to the I / F unit 104 of the first MFP 100 at the set frequency, and the temperature information of the first MFP 100 cannot be obtained. Cannot recover, at time T 3, the second MFP 200 determines that an abnormality due to high temperature has occurred in the power supply system of the first MFP 100 by the controller 201, and the I / F unit 204 determines the power of the first MFP 100. The temperature abnormality information in which an abnormality due to high temperature has occurred in the system unit and the received temperature information of the first MFP 100 are transmitted to the management center 401. That is, both the operation state of the temperature abnormality information notification and the operation state of temperature information transmission to the management center 401 by the second MFP 100 are YES.

  In the embodiment of the present invention, the I / F of the second MFP 200 is set at a preset frequency in a preset postponement period (that is, the time difference between the time T2 and the time T3) immediately after the time T2. The unit 204 is configured to continue to periodically communicate with the I / F unit 104 of the first MFP 100. However, instead of the preset deferment period, the regular communication is performed with the preset number of extensions. If the temperature information of the first MFP 100 cannot be obtained until the preset number of times of extension ends, the second MFP 200 displays the temperature abnormality information and the received temperature information of the first MFP 100. It may be configured to transmit to the management center 401.

  When the temperature abnormality information is transmitted to the management center 401 by the second MFP 200 at this time T3, the I / F unit 204 of the second MFP 200 periodically transmits to the I / F unit 104 of the first MFP 100. The communication state and the reception of temperature information of the first MFP 100 are stopped, that is, the temperature information acquisition operation state of the second MFP 200 is NO.

  As described above, when an abnormality due to high temperature occurs in the power supply system unit of the first MFP 100, even if the first MFP 100 cannot detect the abnormality, the second MFP 200 replaces the first MFP 100 and detects the abnormality. Can be reliably and easily performed.

  With reference to FIG. 5, an operation for detecting an abnormality when a sign of abnormality occurs due to another cause such as lightning in the first MFP 100 will be described. FIG. 5 is a timing chart for explaining the operation and state of the electronic device system 10 after a sign of abnormality due to lightning according to the embodiment of the present invention is detected. In FIG. 5, the same reference numerals are given to portions overlapping with those in FIG. 3, and description thereof is omitted.

  As shown in FIG. 5, when the sign detection number Nf of the first MFP 100 detected by the sign detection unit 107 exceeds the reference number Nf0 at time T0, the I / F unit 204 of the second MFP 200 , Periodically communicates with the I / F unit 104 of the first MFP 100 via the network 400 and receives temperature information of the first MFP 100, that is, the operation state of the second MFP 200 for acquiring temperature information is YES. Become.

  After that, at time T4, when the sign detection number Nf of the first MFP 100 detected by the sign detection unit 107 becomes equal to or less than the reference number Nf0, the I / F unit 204 of the second MFP 200 Periodic communication with the I / F unit 104 and reception of temperature information of the first MFP 100 are stopped, that is, the operation state of the second MFP 200 for acquiring temperature information returns to NO.

  As described above, when there is no sign of an abnormality caused by a surge such as lightning, the communication load from the second MFP 200 to the first MFP 100 is terminated, so that the processing load on the entire electronic device system 10 can be suppressed. it can.

  An operation for detecting an abnormality when the power of the first MFP 100 is normally turned off will be described with reference to FIG. FIG. 6 shows the electronic apparatus system 10 including the ON / OFF information of the first MFP 100 and the result of the power supply stop permission determination of the second MFP 200 after the abnormality sign according to the embodiment of the present invention is detected. It is a timing chart explaining the operation | movement and a state. In FIG. 6, the same reference numerals are given to the same portions as those in FIG. 3 and the description thereof is omitted.

  As shown in FIG. 6, since the number Nf0 of sign detections of the first MFP 100 exceeds the reference number Nf0 at time T0, the power stop permission determination result of the second MFP 200 is set to be NG. . That is, in the period when the first MFP 100 has a sign of abnormality (that is, the period from time T0 to time T5 and the period after time T6 to be described later), the first MFP 100 is not turned off normally. Control is performed so that the abnormality detection function of the second MFP 200 is not turned off. As described above, during the period when the abnormality of the first MFP 100 has occurred, the abnormality detection by the second MFP 200 can be reliably maintained by not stopping the abnormality detection function of the second MFP 200.

  Thereafter, when the power of the first MFP 100 is normally turned off at time T5, the I / F unit 204 of the second MFP 200 performs periodic communication with the I / F unit 104 of the first MFP 100, Reception of temperature information and ON / OFF information of the first MFP 100 is temporarily stopped, that is, the operation state of the second MFP 200 for acquiring temperature information is temporarily NO. At this time, since the power supply of the first MFP 100 is normally turned off, the result of the power supply stop permission determination of the second MFP 200 is set to be OK.

  Thereafter, when the power of the first MFP 100 is turned on again at time T6, the I / F unit 204 of the second MFP 200 performs periodic communication with the I / F unit 104 of the first MFP 100, the first The reception of the temperature information and the ON / OFF information of the first MFP 100 is resumed, and the result of the power supply stop permission determination of the second MFP 200 becomes NG again.

  As described above, even when the first MFP 100 is normally turned off, that is, when the regular communication from the second MFP 200 is normally stopped, it is possible to prevent erroneous determination that an abnormality has occurred. The processing load of the entire electronic device system 10 can be suppressed.

  With reference to FIG. 7, an operation of detecting an abnormality when both the first MFP 100 and the second MFP 200 are normally turned off will be described. FIG. 7 shows an electronic apparatus when the third MFP 300 detects the occurrence of an abnormality in the first MFP 100 on behalf of the second MFP 200 after the abnormality sign according to the embodiment of the present invention is detected. 3 is a timing chart for explaining the operation and state of the system 10. In FIG. 7, parts that are the same as those in FIG.

  As shown in FIG. 7, when the power of the first MFP 100 is normally turned off at time T7 and turned on again at time T8, the power of the second MFP 200 is turned on from time T7 to time T8. (I.e., a period in which the result of the power supply stop permission determination of the second MFP 200 is OK).

  Thereafter, when the power of the first MFP 100 is turned on again, the I / F of the second MFP 200 is detected when the sign detection number Nf of the first MFP 100 detected by the sign detection unit 107 exceeds the reference number Nf0. Since the power of unit 204 is OFF, it is not possible to resume periodic communication with first MFP 100. The acting third MFP 300 may be determined when the second MFP 200 is turned off, or may be determined by searching for an MFP that is turned on in a predetermined order when the first MFP 100 is turned on. Is optional.

  At this time, at time T9 immediately after the first MFP 100 is restarted (that is, time T8), the third MFP 300 that is turned on is substituted for the second MFP 200 and its I / F unit 304 is connected to the network 400. Is periodically communicated to the I / F unit 104 of the first MFP 100 to receive the temperature information and ON / OFF information of the first MFP 100, that is, the operation state of the temperature information acquisition of the third MFP 300 is YES It becomes.

  As described above, when the abnormality detection function of the second MFP 200 is normally turned off, when an abnormality due to high temperature occurs in the first MFP 100, the third MPF 300 performs abnormality detection on behalf of the second MFP 200. By doing so, the abnormality detection in the electronic device system 10 can be maintained quickly and flexibly. In addition, when an abnormality due to a high temperature occurs in the first MFP 100, the degree of freedom in selecting an abnormality detection device increases.

  An electronic device, an electronic device system, and a program according to the present invention relate to an electronic device, an electronic device system, and a program that can detect an abnormality due to high temperature.

10 electronic device system 100 first MFP
101 controller 102 CPU
103 HDD
104 I / F section 105 UI section 106 Image forming section 107 Predictive detection section 108 Fixing section 109 Optional device 110 Power switch 111 First low-voltage power supply 112 Second low-voltage power supply 113 Temperature sensor 114 Temperature sensor 115 Power supply wiring 200 Second MFP
201 Controller 202 CPU
203 HDD
204 I / F unit 300 Third MFP
301 controller 302 CPU
303 HDD
304 I / F unit 400 Network 401 Management center 402 PC
403 PC
500 Commercial power

Claims (11)

An anomaly detection means for detecting anomalies due to high temperature;
A sign detection means for detecting a sign of abnormality due to high temperature;
When detecting a sign of abnormality due to high temperature by the sign detection means, output means for outputting power-on information, sign occurrence information and the detection result by the abnormality detection means,
An electronic device.   The electronic device according to claim 1, wherein a plurality of the abnormality detection means are provided for each of a plurality of target parts.   The electronic apparatus according to claim 1, wherein the sign detection unit detects a voltage or current abnormality in a power supply circuit. An abnormality detection means for detecting an abnormality due to a high temperature, a sign detection means for detecting a sign of an abnormality due to a high temperature, and when a sign of an abnormality due to a high temperature is detected by the sign detection means, power-on information, sign occurrence information and the abnormality detection A first electronic device having output means for outputting a detection result by the means;
A second electronic device having determination means for determining whether an abnormality due to high temperature has occurred in the first electronic device based on an output result of the output means of the first electronic device;
An electronic device system.   According to the power-on information, the determination unit determines that the first electronic device has a detection result obtained by the abnormality detection unit of the first electronic device regardless of whether the power is turned on. 5. The electronic device system according to claim 4, wherein it is determined that an abnormality due to high temperature has occurred.   5. The second electronic device further includes communication control means for starting communication with the first electronic device when detection of the sign by the sign detecting means of the first electronic device is started. Or the electronic device system of 5.   5. The second electronic device further includes communication control means for ending communication with the first electronic device when detection of the indication by the indication detecting means of the first electronic device is completed. Or the electronic device system of 5.   The second electronic device further includes a prohibiting unit that controls to prohibit power-off of the second electronic device when a sign is detected by the sign detecting unit of the first electronic device. The electronic device system according to claim 4.   And a third electronic device further comprising determination means for determining whether or not an abnormality due to high temperature has occurred in the first electronic device based on an output result of the output means of the first electronic device. Item 9. The electronic device system according to any one of Items 4 to 8.   In the third electronic device, when the power supply of the second electronic device is cut off, whether or not an abnormality due to high temperature has occurred in the first electronic device on behalf of the second electronic device. The electronic device system according to claim 9, which determines whether the An anomaly detection step for detecting anomalies due to high temperatures;
A sign detection step for detecting a sign of abnormality due to high temperature;
When detecting a sign of abnormality due to high temperature, an output step of outputting power-on information, sign occurrence information and the detection result by the abnormality detection means;
A program that causes a computer to execute.

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